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CN102792621A - Method for processing CSI-RS in wireless communication system - Google Patents

Method for processing CSI-RS in wireless communication system Download PDF

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Publication number
CN102792621A
CN102792621A CN2011800135499A CN201180013549A CN102792621A CN 102792621 A CN102792621 A CN 102792621A CN 2011800135499 A CN2011800135499 A CN 2011800135499A CN 201180013549 A CN201180013549 A CN 201180013549A CN 102792621 A CN102792621 A CN 102792621A
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csi
comp
subframe
sub
prb
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CN102792621B (en
Inventor
金润善
韩臸奎
金圣泰
延明勋
单成
李仁镐
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Samsung Electronics Co Ltd
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Samsung Electronics Co Ltd
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • H04L1/02Arrangements for detecting or preventing errors in the information received by diversity reception
    • H04L1/06Arrangements for detecting or preventing errors in the information received by diversity reception using space diversity
    • H04L1/0618Space-time coding
    • H04L1/0675Space-time coding characterised by the signaling
    • H04L1/0693Partial feedback, e.g. partial channel state information [CSI]
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B17/00Monitoring; Testing
    • H04B17/30Monitoring; Testing of propagation channels
    • H04B17/309Measuring or estimating channel quality parameters
    • H04B17/318Received signal strength
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04JMULTIPLEX COMMUNICATION
    • H04J11/00Orthogonal multiplex systems, e.g. using WALSH codes
    • H04J11/0023Interference mitigation or co-ordination
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • H04L1/0001Systems modifying transmission characteristics according to link quality, e.g. power backoff
    • H04L1/0002Systems modifying transmission characteristics according to link quality, e.g. power backoff by adapting the transmission rate
    • H04L1/0003Systems modifying transmission characteristics according to link quality, e.g. power backoff by adapting the transmission rate by switching between different modulation schemes
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • H04L1/0001Systems modifying transmission characteristics according to link quality, e.g. power backoff
    • H04L1/0009Systems modifying transmission characteristics according to link quality, e.g. power backoff by adapting the channel coding
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L25/00Baseband systems
    • H04L25/02Details ; arrangements for supplying electrical power along data transmission lines
    • H04L25/0202Channel estimation
    • H04L25/0224Channel estimation using sounding signals
    • H04L25/0226Channel estimation using sounding signals sounding signals per se
    • HELECTRICITY
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    • H04L5/0014Three-dimensional division
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    • HELECTRICITY
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
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    • H04L5/0053Allocation of signaling, i.e. of overhead other than pilot signals
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
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    • H04L5/003Arrangements for allocating sub-channels of the transmission path
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
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    • H04W72/23Control channels or signalling for resource management in the downlink direction of a wireless link, i.e. towards a terminal
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
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    • H04W72/50Allocation or scheduling criteria for wireless resources
    • H04W72/54Allocation or scheduling criteria for wireless resources based on quality criteria
    • H04W72/542Allocation or scheduling criteria for wireless resources based on quality criteria using measured or perceived quality
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B17/00Monitoring; Testing
    • H04B17/20Monitoring; Testing of receivers
    • H04B17/24Monitoring; Testing of receivers with feedback of measurements to the transmitter
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • H04L1/0001Systems modifying transmission characteristics according to link quality, e.g. power backoff
    • H04L1/0023Systems modifying transmission characteristics according to link quality, e.g. power backoff characterised by the signalling
    • H04L1/0026Transmission of channel quality indication
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • H04L1/0001Systems modifying transmission characteristics according to link quality, e.g. power backoff
    • H04L1/0023Systems modifying transmission characteristics according to link quality, e.g. power backoff characterised by the signalling
    • H04L1/0027Scheduling of signalling, e.g. occurrence thereof
    • HELECTRICITY
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    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • H04L1/02Arrangements for detecting or preventing errors in the information received by diversity reception
    • H04L1/06Arrangements for detecting or preventing errors in the information received by diversity reception using space diversity
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L25/00Baseband systems
    • H04L25/02Details ; arrangements for supplying electrical power along data transmission lines
    • H04L25/03Shaping networks in transmitter or receiver, e.g. adaptive shaping networks
    • H04L25/03006Arrangements for removing intersymbol interference
    • H04L2025/0335Arrangements for removing intersymbol interference characterised by the type of transmission
    • H04L2025/03426Arrangements for removing intersymbol interference characterised by the type of transmission transmission using multiple-input and multiple-output channels
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L25/00Baseband systems
    • H04L25/02Details ; arrangements for supplying electrical power along data transmission lines
    • H04L25/03Shaping networks in transmitter or receiver, e.g. adaptive shaping networks
    • H04L25/03006Arrangements for removing intersymbol interference
    • H04L2025/03777Arrangements for removing intersymbol interference characterised by the signalling
    • H04L2025/03802Signalling on the reverse channel
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/003Arrangements for allocating sub-channels of the transmission path
    • H04L5/0078Timing of allocation
    • H04L5/0082Timing of allocation at predetermined intervals
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/0091Signaling for the administration of the divided path
    • H04L5/0092Indication of how the channel is divided
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/50Allocation or scheduling criteria for wireless resources
    • H04W72/54Allocation or scheduling criteria for wireless resources based on quality criteria
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02DCLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
    • Y02D30/00Reducing energy consumption in communication networks
    • Y02D30/70Reducing energy consumption in communication networks in wireless communication networks

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  • Engineering & Computer Science (AREA)
  • Signal Processing (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Quality & Reliability (AREA)
  • Power Engineering (AREA)
  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Mobile Radio Communication Systems (AREA)

Abstract

A method for processing a Channel State Information Reference Signal (CSI-RS) in a wireless communication system based on a multiple access scheme is provided. The CSI-RS transmission method defines a plurality of CSI-RS patterns, assigns the CSI-RS patterns to individual cells, uses the CSI-RSs alternately per Physical Resource Block (PRB) so as to utilize the transmission powers of all antenna ports for transmitting CSI-RSs, transmits Coordinated Multi Point (CoMP) CSI-RSs and non-CoMP CSI-RSs separately, and mutes specific resources in association with the CSI-RS pattern of adjacent cells.

Description

Be used to handle the method for CSI-RS in the wireless communication system
Technical field
The present invention relates to a kind of wireless communication system.More specifically, the present invention relates to a kind of method of the processing channel state information reference signals in wireless communication system (CSI-RS) based on the multiple access scheme.
Background technology
In the third generation (3G) advanced person's mobile radio system standard, specified two types reference signal, be called public reference signal (CRS) and DRS (Dedicated Reference Signal) (DRS).CRS is called as (cell-specific) RS or the public RS (CRS) of the specific cell in 3G partner program (3GPP) Long Term Evolution (LTE) standard, and is kept watch on by all subscriber equipmenies (UE) in the sub-district of corresponding base station.Defeated for multi-antenna transmitting, the definition reference signal mode is to distinguish between the antenna port that is used for channel estimating and measurement.In the LTE system, can support 4 antenna ports at most.DRS representes the reference signal of sending discretely and being answered by the indicated UE in base station from CRS.In 3GPP advanced person's LTE (LTE-A) system, this reference signal is known as RS, DRS or the demodulated reference signal (DMRS) of particular UE, and is used to be supported in the data traffic channels transmission based on the precoding of non-code book that has of base station.
In LTE-A system,, also send demodulated reference signal (DM-RS) and be used to support 8 layers channel estimating except aforementioned CRS and DRS as the advanced form of LTE system.
Fig. 1 illustrates the figure of configuration that in the LTE system, is used to send radio frames, subframe and the Physical Resource Block (PRB) of CRS according to correlation technique.
With reference to Fig. 1, radio frames is divided into 10 sub-frame, each has 1 millisecond length.This means that radio frames has 10 milliseconds length and is made up of 10 sub-frame, as shown in fig. 1.In Fig. 1, one of subframe of radio frames is formed in reference number 110 expressions.For each subframe, the Node B of evolution (eNB) is carried out transmission with the mode of OFDM (OFDMA) on system bandwidth.One sub-frame comprises a plurality of Physical Resource Block (PRB).A PRB comprises 12 number of sub-carrier.For a sub-frame, at the be spaced subcarrier of frequency domain with rule.In Fig. 1, one of PRB of this system bandwidth is formed in reference number 120 expressions.In the LTE of Fig. 1 signal structure, rely on the number that this system bandwidth is confirmed PRB.
PRB 120 is the time-frequency resources zone, and is represented like reference number 130.Reference number 130 like Fig. 1 is represented, the time-frequency resources zone that each PRB is made up of 12 subcarriers on the frequency domain and the 14OFDMA symbol duration on the time domain.Be known as resource element (RE) by a number of sub-carrier and the defined resource units of OFDM symbol duration, and a RE can transport a data symbol or reference signal symbol.
PRB 130 is made up of 12 subcarriers and 14OFDM symbol duration.This means that PRB 130 is made up of 168RE altogether.The control area is done in first three OFDM symbol duration distribution of this PRB 130, and wherein eNB uses control channel to be used to send control information, and UE can use this control information to receive Traffic Channel.Though define the control area by first three OFDM symbol duration, depend on the decision of eNB, it can be configured to previous or two OFDM symbol durations.
In Fig. 1, reference number 140 expression data RE use in sending Traffic Channel.Reference number 150 expression CRS RE are used to send the channel estimating that is used for UE and the CRS of measurement.Because the position of these data RE and CRS RE is known to eNB and UE, so UE can correctly receive CRS and Traffic Channel among the PRB.Only if outside stating clearly, otherwise all in the following description index are since 0.For example, in Fig. 1, form 14OFDM symbol from 0 to 13 produce index of this PRB.
Fig. 2 illustrates the figure of resource to measure to the eNB reporting channel quality that in the LTE system, distributes for UE according to correlation technique.
With reference to Fig. 2, UE is the channel quality that comprises interior all PRB of subframe 230 these band system band of measurement of a plurality of PRB.In order to measure the channel quality among each PRB, UE uses the CRS220 that is sent by eNB.Owing in all PRB, send CRS with identical transmitted power, so the reception signal strength signal intensity of CRS in receiving in each PRB through contrast, UE can confirm that which PRB has higher channel quality relatively.Equally, depend on absolute reception signal strength signal intensity, can confirm the data transfer rate that each PRB can support.Channel quality information is mapped as the form of channel feedback information, and then uses and report to eNB like the 240 represented uplink control channels of reference number among Fig. 2.Based on the channel feedback information of being sent by UE, eNB carries out downlink transmission in subframe 251,252,253,254 and 255.ENB can obtain the information of the data transfer rate of supporting about UE, preferred precoding and preferred PRB based on the channel feedback information of being sent by UE, and carries out downlink scheduling and adaptive modulation and coding (AMC) based on the information that is obtained.
In Fig. 2, eNB used channel feedback information 240 before receiving next channel feedback information 260.Though in Fig. 2, only described a UE transmitting channel feedback information, the system of real world typically is designed to a plurality of UE transmitting channel feedback information simultaneously.
Summary of the invention
Technical problem
Above-described method has a lot of problems.For example, in the LTE system, UE comes measure channel quality based on the CRS that is sent by eNB.Using CRS as shown in Figure 2 to come under the situation of measure channel quality, the number of plies that eNB uses multiple-input and multiple-output (MIMO) technology to send receives the antenna port numerical limitations of CRS.According to standard, the LTE system can support nearly 4 antenna ports.Owing to do not support the CRS antenna port more than four, the MIMO of eNB transmission is restricted to maximum four layers.
UE's is that eNB must send CRS always based on the channel estimating of CRS and another problem of measurement.Correspondingly, should send extra CRS in order to support more than four antenna ports.This means finite wireless resources too much concentrated to be used to send to be used for the CRS that channel estimating is measured, cause the bandwidth inefficiency.
Solution
One side of the present invention is to solve the problems referred to above and/or shortcoming at least, and following at least advantage is provided.So; One side of the present invention provides the method for transmitting channel state information reference signals (CSI-RS) in a kind of Long Term Evolution the advanced person (LTE-A) system, and it can improve resource management efficient and the channel measurement efficient of subscriber equipment (UE) of the Node B (eNB) of evolution.
Another aspect of the present invention provides the method for a kind of CSI-RS of transmission, and it can improve RRM efficient at each eNB, and it has separated the CSI-RS that sends in the sub-district at corresponding eNB with frequency domain in time domain at a plurality of eNB.
According to an aspect of the present invention, a kind of method of in OFDM (OFDMA) system, sending CSI-RS is provided.This method comprises: the CSI-RS mode type confirmed in Physical Resource Block (PRB) index based on subframe; When this subframe of supposition will transport CSI-RS the time, based on this CSI-RS mode type with first the CSI-RS to the N antenna port distribute to PRB first to N OFDM (OFDM) symbol; And send and to comprise the subframe of having shone upon first to the CSI-RS of N antenna port PRB, wherein first to the N CSI-RS mode type is mapped to first CSI-RS to the N antenna port with mode alternately first to the N OFDM symbol of this PRB.
According to a further aspect in the invention, a kind of method of in the OFDMA system, sending CSI-RS is provided.This method comprises: confirm to coordinate the interior sub-district of multiple spot (CoMP) collection and shared about CoMP CSI-RS information transmitted in these sub-districts; When sending subframe, determine whether to think that this subframe will transport CSI-RS; When thinking that this subframe will be transported CSI-RS, confirm whether this CSI-RS is CoMPCSI-RS; And, sends this CSI-RS this CoMP CSI-RS when being CoMP CSI-RS; And when this CSI-RS is not CoMP CSI-RS; Send non-CoMP CSI-RS; Wherein CoMP CSI-RS is to be the CSI-RS with the downlink channel of measuring these sub-districts that subscriber equipment (UE) sends by a plurality of sub-districts, and the CoMP collection is to participate in being used to cooperate the set of the sub-district of sending this CoMP CSI-RS.
In accordance with a further aspect of the present invention, provide a kind of in OFDM (OFDMA) system the method for transmitting channel state information-reference signal (CSI-RS).This method comprises: share about the CSI-RS pattern of neighbor cell and the information of CSI-RS antenna port number; When sending subframe, determine whether to think that through analyzing this CSI-RS pattern this subframe will transport CSI-RS; When the CSI-RS transmission time then, send the subframe of transporting this CSI-RS according to this CSI-RS pattern; And, send and wherein to have suppressed the subframe that (mute) and the CSI-RS antenna port of neighbor cell are counted the resource element (RE) of corresponding number in the CSI-RS transmission time of one of neighbor cell.
To those skilled in the art, according to below in conjunction with detailed description accompanying drawing, that disclose example embodiment of the present invention, it is clear that others of the present invention, advantage and notable feature will become.
Beneficial effect
According to the method for the processing CSI-RS of example embodiment of the present invention can be in different PRB the CSI-RS of transmitting antenna port alternately so that manage the transmitted power of all antenna ports of eNB effectively.According to the method for the processing CSI-RS of example embodiment of the present invention to the transmission location of the different CSI-RS pattern of cell allocation with the CSI-RS that avoids different districts; Suppressing signal thus disturbs; Send non-CoMP CSI-RS and CoMP CSI-RS effectively, and allow assist the down effectively measured channel of UE in the resource that suppresses adjacent eNB transmission CSI-RS place.
Description of drawings
According to the description below in conjunction with accompanying drawing, the above and others of particular exemplary embodiment of the present invention, feature and advantage will become clearer, wherein:
Fig. 1 illustrates according to correlation technique, in Long Term Evolution (LTE) system, is used to send the figure of configuration of radio frames, subframe and the Physical Resource Block (PRB) of public reference signal (CRS);
Fig. 2 illustrates according to correlation technique, in the LTE system be that subscriber equipment (UE) distributes, with the figure of the resource measured to the Node of evolution B (eNB) reporting channel quality;
Fig. 3 illustrates according to figure example embodiment of the present invention, the transmission of the channel state information reference signals (CSI-RS) of eNB in advanced person's LTE (LTE-A) system;
Fig. 4 illustrates the figure in the position of temporal frequency lattice according to CSI-RS example embodiment of the present invention, that be used for the LTE-A system;
Fig. 5 is the figure that illustrates according to the PRB with the resource element (RE) that distributes for transmission CSI-RS example embodiment of the present invention, in the LTE-A system;
Fig. 6 be illustrate according to example embodiment of the present invention, in the LTE-A system, have a figure for the PRB that alternately sends the RE that CSI-RS distributes;
Fig. 7 illustrates according to CSI-RS mode type A and CSI-RS mode type B example embodiment of the present invention, with Fig. 6 in system bandwidth to send the figure of the rule of CSI-RS;
Fig. 8 be illustrate according to example embodiment of the present invention, in having the different PRB of four kinds of CSI-RS patterns the figure of the rule of the CSI-RS of transmitting antenna port alternately;
Fig. 9 be illustrate according to example embodiment of the present invention, design is with the figure of the CSI-RS pattern of distributing to a plurality of sub-districts in the GSM;
Figure 10 be illustrate according to example embodiment of the present invention, adopt figure like the cellular network layout of the GSM of the CSI-RS pattern that defines among Fig. 9;
Figure 11 be illustrate according to example embodiment of the present invention, design is with the figure of the CSI-RS pattern of distributing to a plurality of sub-districts in the GSM;
Figure 12 be illustrate according to example embodiment of the present invention, defined the figure of the PRB in three CSI-RS zones therein;
Figure 13 be illustrate according to example embodiment of the present invention, in comprising the cellular environment of various types of sub-districts, send the figure of the rule of CSI-RS;
Figure 14 A to 14C be illustrate according to example embodiment of the present invention, design is with the figure of the CSI-RS pattern of distributing to a plurality of sub-districts in the GSM;
Figure 15 be illustrate according to example embodiment of the present invention, interference-free sends the figure of the rule of CSI-RS in a plurality of sub-districts;
Figure 16 illustrates according to the figure of rule example embodiment of the present invention, in subframe, send the CSI-RS of a plurality of sub-districts with different CSI-RS patterns;
Figure 17 sends the figure of the rule of coordinating multiple spot (CoMP) CSI-RS and non-CoMP CSI-RS according to example embodiment of the present invention, in the sub-district of GSM;
Figure 18 be illustrate according to example embodiment of the present invention, in the sub-district of GSM, send the figure of the rule of CoMP CSI-RS and non-CoMP CSI-RS;
Figure 19 be illustrate according to example embodiment of the present invention, in GSM, send the figure of the rule of CoMP CSI-RS and non-CoMP CSI-RS;
Figure 20 be illustrate according to example embodiment of the present invention, in GSM, use inhibition scheme (muting scheme) to send the figure of the rule of CSI-RS;
Figure 21 be illustrate according to example embodiment of the present invention, in GSM, use the inhibition scheme to send the figure of the rule of CSI-RS;
Figure 22 be illustrate according to example embodiment of the present invention, the inhibition scheme is applied to a plurality of sub-districts with the squint figure of the rule in the situation of sending CSI-RS of different subframes;
Figure 23 be illustrate according to example embodiment of the present invention, the inhibition scheme is applied to the situation of CSI-RS is sent in two sub-districts in some PRB the figure of rule;
Figure 24 illustrates the flow chart that receives the method for CSI-RS according to UE in the GSM of multiple CSI-RS pattern work example embodiment of the present invention, that in utilizing Fig. 9 or Figure 11, describe;
Figure 25 illustrates the flow chart that receives the method for CSI-RS in utilizing Fig. 9 or Figure 11 according to UE in the GSM of multiple CSI-RS pattern work example embodiment of the present invention, that use inhibition scheme is described;
Figure 26 be illustrate according to example embodiment of the present invention, eNB uses the inhibition scheme to send the figure of the method for CSI-RS in GSM;
Figure 27 be illustrate according to example embodiment of the present invention, eNB sends the figure of the method for non-CoMP CSI-RS and CoMP CSI-RS in GSM; And
Figure 28 be illustrate according to example embodiment of the present invention, UE receives the flow chart of the method for non-CoMP CSI-RS and CoMP CSI-RS in GSM.
All in the accompanying drawing, should be noted that similar reference number is used to describe same or analogous key element, characteristic and structure.
Embodiment
Description with reference to the accompanying drawings is provided, to help to complete understanding like claims and the defined example embodiment of the present invention of equivalents thereof.It comprises that various specific details to help understanding, are only exemplary but will be used as these.Correspondingly, one of skill in the art will recognize that under situation about not departing from the scope of the present invention with spirit, can carry out variations and modifications the embodiments described herein.In addition, for clear and simple and clear, the description that can omit known function and structure.
Term that uses in description below and the claim and vocabulary are not limited to their written meanings, but only are used for enabling the clear the present invention that also as one man understands by the inventor.So, for a person skilled in the art should be obviously, only the purpose from signal provides describing below of example embodiment of the present invention, rather than in order to limit the purpose of liking claim and the defined invention of equivalents thereof enclosed.
Be understood that one, one of singulative and this comprise plural, only if clear from context point out except.Thereby, for example, referring to of a parts surface comprised referring to one or more such surfaces.
Example embodiment of the present invention relates to a kind of based on transmitting channel state information reference signals (CSI-RS) in such as the GSM of the multiple access scheme of the OFDM (OFDMA) that uses multicarrier and control the method for CSI-RS transmission, and wherein subscriber equipment (UE) comes measure channel quality based on the CSI-RS that the Node B (eNB) of evolution sends.That is, example embodiment of the present invention has proposed the method that a kind of transmission/reception reference signal is also managed the reference signal transmission in many sub-districts effectively.
GSM has developed at a high speed, the high-quality packet data communication system, is used for except basic voice service various multimedia services being provided also.For this reason, the standardization body's employing such as the 3rd generation partner program (3GPP), 3GPP2 and Institute of Electrical and Electric Engineers (IEEE) comes the standardization next generation mobile communication system based on the multiple access scheme of multicarrier.Recently, developed such as the various mobile communication standards of 3GPP Long Term Evolution (LTE), 3GPP2 Ultra-Mobile Broadband (UMB) and IEEE 802.16m and supported high-speed, high-quality wireless packet data transmission service based on multicarrier multiple access scheme.
Such as the advanced person of LTE, UMB and 802.16m the 3rd generation (3G) GSM based on the work of multicarrier multiple access scheme, and adopt various technology such as multiple-input and multiple-output (MIMO), beam shaping, adaptive modulation and coding (AMC) and channel sensitive scheduling to improve efficiency of transmission.These transmission technologys are considered and the concentrating or the adjustment of data transfer rate of the transmitted power of many antennas, and use the efficiency of transmission of enhancing to improve throughput of system through optionally sending data to the user with good channel quality.Most of these technology are based on the channel condition information between base station (BS) (for example eNB) and terminal (for example UE or the mobile radio station (MS)), and CSI-RS is as this channel condition information.ENB can be that the down link that is installed on a position sends and the up link receiving equipment, and eNB can operate a plurality of sub-districts.GSM comprises the eNB that disperses on a plurality of geography, and each eNB manages the transmission/reception of a plurality of sub-districts.
Typically, GSM is worked under limited time, frequency and transmitted power resource.So, distribute a large amount of resources for reference signal and just reduced the resource of distributing to traffic channel transmission, cause the minimizing of transmission quantity.In this case, though improved channel measurement and estimated performance, the minimizing of data amount transmitted causes the deterioration of whole system throughput.Therefore need be the transmission of reference signal and Traffic Channel Resources allocation effectively, consider the performance of overall system throughput with optimization.
Reference signal is used to measure the channel status (the for example signal strength signal intensity of every channel and distortion, interference and Gaussian noise) between base station and the UE and the modulation and the decoding of the data symbol confirming based on measurement result to be received.The intensity of the reference signal that receiver is measured is received, sent with the transmitted power of promising to undertake by transmitter is to confirm the radio channel state for this transmitter.Radio channel state is used for confirming the data transfer rate of receiver to the transmitter request.
3G mobile communication standard such as the advanced person of advanced LTE (LTE-A) of 3GPP or IEEE 802.16m adopts OFDM/OFDM (OFDM/OFDMA) as multicarrier multiple access transmission plan.In the GSM based on multicarrier multiple access scheme, the symbolic number and the sub-carrier number of frequency domain that transport the time domain of reference signal can influence channel estimating and measurement performance.Equally, the power influences channel estimating and the measurement performance that distribute for the transmission of reference signal.The time, frequency and the power that distribute are many more, and channel estimating and measurement performance improve manyly more, and this causes the improvement of data symbol demodulation code performance and channel status measuring accuracy.
But, because the resource such as time, frequency and transmitted power is limited in typical GSM, so be used for the minimizing of resource that the excessive increase of the resource allocation of reference signal causes being used for the transmission of data-signal.Because this reason, should the taking into account system throughput confirm to be used for the resource allocation of reference signal.
Example embodiment of the present invention has proposed the method that a kind of transmission/reception reference signal is used for the channel quality measurement of wireless channel and manages the reference signal transmission of many sub-districts effectively.
Fig. 3 illustrates according to figure example embodiment of the present invention, that the CSI-RS of eNB sends in the LTE-A system.
With reference to Fig. 3, in the LTE-A system, on 1 millisecond unit of time domain and frequency domain, carry out down link in 1 Physical Resource Block (PRB) and send.Here, PRB is made up of 12 subcarriers.1 millisecond of duration is made up of the 14OFDM symbol., LTE or LTE-A system realize every PRB 12 subcarriers and per 1 millisecond of 14OFDM symbol when using subcarrier that the spacing with 15KHz separates with normal Cyclic Prefix.But LTE or LTE-A system can use with the spaced subcarrier of 7.5KHz and the Cyclic Prefix of expansion equally.
In Fig. 3, eNB sends subframe 340 to 351.In this case, use the subframe 340,345 and 350 in the subframe 340 to 351 to transport CSI-RS.That is, send CSI-RS with the interval of 5 milliseconds or 5 subframes.If subframe 340 is transported CSI-RS, this means in one or more PRB of subframe 340 and send CSI-RS.In Fig. 3, transport the PRB of CSI-RS among a plurality of PRB of reference number 335 expression composition subframes 340.In PRB 335, send independent CSI-RS 331,332,333 and 334 at corresponding antenna port.Just, send CSI-RS 331 at antenna port 0 and 1, and send CSI-RS 332 at antenna port 2 and 3.
In Fig. 3, the PRB of CSI-RS is not transported in reference number 336 expressions.Send the PRB that do not transport CSI-RS and form contrast with the form of reference number 336 expression with the PRB that transports CSI-RS 335.
The LTE-A system be different from LTE system part be LTE-A UE use CSI-RS 331,332,333 and 334 rather than CRS 320 carry out channel measurement.
In order to design efficient CSI-RS delivery plan, should confirm in the T/F lattice, to send the position of CSI-RS.
Fig. 4 is the figure of the position of CSI-RS in the temporal frequency lattice about the LTE-A system that illustrates according to example embodiment of the present invention.
As shown in Figure 4, this PRB comprises various types of resource elements (RE).Here, define RE, and RE is used to the least resource unit that sends in LTE and the LTE-A system by a number of sub-carrier of frequency domain and an OFDM symbol duration of time domain.In Fig. 4, RE of each square indication.Here, there are altogether 12 * 14 squares and therefore 12 * 14 RE altogether.
With reference to Fig. 4, first three OFDM symbol duration (promptly the 0th to the 2OFDM symbol) is the control area, only transmits control signal therein and CRS (for example CRS 410).This control area receives the supervision of the LTE UE that in this LTE-A system, works, and thereby need not transport CRI-RS.From the 3rd to the end OFDM symbol duration (promptly the 3rd to the 13OFDM symbol) is the data area, can send UE DRS (Dedicated Reference Signal) that is used for channel estimating (or at LTE-A, the RS of particular UE) and the CRS of traffic channel signal, LTE therein.Owing to can not send CSI-RS in the control area, it must (for example at RE 430) send in the data area.Though can send CSI-RS in the data area, should avoid being placed on RE and make this CSI-RS can influence traditional LTE transmit operation there.Should not be representational RE that CSI-RS distributes and be the the 4th, the 7th, the 8th and the RE of 11OFDM symbol; 420 represented like the reference number of Fig. 4, be the RE that the reference signal of the particular UE of LTE keeps, and as the reference number of Fig. 4 is 440 represented, be the RE of reference signal reservation of the particular UE of LTE-A.
Fig. 5 is the figure that illustrates according to the PRB with the RE that distributes for transmission CSI-RS example embodiment of the present invention, in the LTE-A system.
With reference to Fig. 5, the CSI-RS that is arranged in RE 510,520,530,540,550 and 560 is the only CSI-RS of each OFDM symbol of this PRB.This means, in transporting the OFDM symbol of CSI-RS, at antenna port only to send a CSI-RS.Consider the transmit power management of this eNB, it is inefficient sending a CSI-RS at the individual antenna port in the OFDM symbol.If in an OFDM symbol, only send a CSI-RS as shown in Figure 5,, then wasted the transmitted power of residue antenna port even when this eNB has been configured a plurality of antenna port for the individual antenna port.In the exemplary of in this PRB, sending the CSI-RS that is used for four antenna ports as shown in Figure 5, the OFDM symbol with RE 510 transports the CSI-RS that is used for specific antenna port.Problem is, only is used for the CSI-RS of an antenna port because send, so be not utilized as the transmitted power that other three antenna ports distribute.
This problem exists equally when in the OFDM symbol, sending the CSI-RS that is used for two antenna ports.In same OFDM symbol, send the CSI- RS 540 and 570 that is used for antenna port separately.Problem is, when the antenna port number of this eNB greater than 2 the time, do not have to utilize the transmitted power on the antenna port except sending the antenna port that CSI- RS 540 and 570 is used for as stated.
A kind of method of transmitted power of all antenna ports that use this eNB is in an OFDM symbol, to send the CSI-RS that is used for all antenna ports.Yet the inconsiderate place of this method is: a PRB only is made up of 12 subcarriers, and the maximum number of antenna port is 8, and some RE can not distribute for CSI-RS.
Example embodiment of the present invention has proposed a kind of method of transmitted power of all antenna ports that utilize this eNB, and wherein this eNB alternately is applied to different PRB with the CSI-RS of antenna port.
Fig. 6 be illustrate according to example embodiment of the present invention, in the LTE-A system, have a figure for the PRB that alternately sends the RE that CSI-RS distributes.
With reference to Fig. 6, this eNB sends CSI-RS at an OFDM symbol and the 2nd OFDM symbol.In order to use the transmitted power of all antenna ports, this eNB sends CSI-RS in a CSI-RS pattern that is used for some PRB with in the 2nd CSI-RS pattern that is used for other PRB.In a CSI-RS pattern, in first of this two contiguous OFDM symbol, send the CSI-RS that is used for the first antenna port collection, and in second of these two contiguous OFDM symbols, send the CSI-RS that is used for the second antenna port collection; And in the 2nd CSI pattern; Send the CSI-RS that is used for the second antenna port collection in the symbol before OFDM (preceding-OFDM symbol), and behind OFDM, send the CSI-RS that is used for the first antenna port collection in the symbol (following-OFDM symbol).
In Fig. 6, this first OFDM symbol can be the 9OFDM symbol in this PRB, and this second OFDM symbol can be the 10OFDM symbol.The one CSI-RS pattern can be CSI-RS mode type A 610, and the 2nd CSI-RS pattern can be CSI-RS mode type B 620.
In Fig. 6, suppose this eNB the 9th and the 10OFDM symbol send CSI-RS.At this time, this eNB can send CSI-RS with CSI-RS mode type A 610 and CSI-RS mode type B 620.In CSI-RS mode type A 610, send the CSI-RS that is used for antenna port 4,5,6 and 7 at the 9OFDM symbol, and send the CSI-RS that is used for antenna port 0,1,2 and 3 at the 10OFDM symbol.Otherwise, in CSI-RS mode type B 620, send the CSI-RS that is used for antenna port 0,1,2 and 3, and send the CSI-RS that is used for antenna port 4,5,6 and 7 at the 10OFDM symbol at the 9OFDM symbol.This eNB will transport half PRB of CSI-RS and will be disposed in the system bandwidth with second half PRB that CSI-RS mode type B 620 transports CSI-RS with CSI-RS mode type A 610.
The CSI-RS that in system bandwidth, defines a plurality of CSI-RS and send among the PRB with same speed has the following advantages.The first, the CSI-RS number that in the OFDM symbol, sends is consistent with the antenna port number.The second, can in a plurality of OFDM symbols, send CSI-RS.
Though in identical OFDM symbol, send the CSI-RS that is used for the different antennae port with CSI-RS mode type B with CSI-RS mode type A; There is the CSI-RS that is used for all antenna ports in the single OFDM symbol duration but use said two kinds of patterns to make simultaneously, at this time can realizes said first advantage.Suppose such exemplary case: system bandwidth comprises two PRB; Wherein first PRB transports the CSI-RS of CSI-RS mode type A and second PRB transports the CSI-RS of CSI-RS mode type B, then the 9th and each of 10OFDM symbol in all send the CSI-RS that is used for all antenna ports.In single OFDM symbol, send under the situation of the CSI-RS that is used for all antenna ports, can use the transmitted power of all antenna ports.Send through using a plurality of OFDM symbols to be used for CSI-RS, can highly freely confirm the transmission position of CSI-RS and realize said second advantage.Suppose in single OFDM symbol and to send the CSI-RS that is used for 8 antenna ports, then can not the the 5th, the 6th, the 12nd and the 13OFDM symbol in send CSI-RS because the the 5th, the 6th, the 12nd and each of 13OFDM symbol in have only 6 RE.
Fig. 7 illustrates according to CSI-RS mode type A and CSI-RS mode type B example embodiment of the present invention, with Fig. 6 in system bandwidth to send the figure of the rule of CSI-RS.
With reference to Fig. 7, part 710 shows exemplary CSI-RS pattern and confirms scheme, wherein based on the PRB index, is that odd number or even number confirm to be to use CSI-RS mode type A 610 or CSI-RS mode type B 620 based on this PRB index promptly.In the part 710 of Fig. 7; Confirm that index is that the PRB of even number (promptly 0,2,4,6) uses CSI-RS mode type A 610 to be used to send CSI-RS, and confirm that index is that the PRB use CSI-RS mode type B 620 of odd number (promptly 1,3,5,7) is used to send CSI-RS.Part 720 shows another exemplary CSI-RS pattern and confirms scheme; Wherein whether have less than the value of peaked half the (be K/2, wherein K is the maximum of this PRB index) and confirm to be to use CSI-RS mode type A 610 or CSI-RS mode type B 620 based on this PRB index.In the part 720 of Fig. 7; Confirm that index uses CSI-RS mode type A 610 less than the peaked half the PRB (being PRB 0 to PRB 2) of PRB index, and confirm that index uses CSI-RS mode type B 620 greater than the peaked half the PRB (being PRB 3 to PRB 5) of PRB index.
Though Fig. 7 describes under two CSI-RS patterns are used to send the hypothesis of CSI-RS, the number of CSI-RS pattern can be generalized to N as follows.Here, suppose that K PRB is present in (maximum that is the PRB index is K) in the system bandwidth.
Solution 1:, use (i mod N) individual CSI-RS mode type if the PRB index is i.
Solution 2:, use [i/ (K/N)] individual CSI-RS mode type if the PRB index is i.
Solution 1 and 2 is supported in the situation of sending CSI-RS among all PRB, but can be applied in all PRB, not send the situation of CSI-RS similarly.(for example per the 5th PRB L=5) sends in the exemplary of CSI-RS, in an identical manner application solution 1 and 2 at every L PRB.Sending under the situation of CSI-RS at L PRB with identical distance on the frequency domain, can confirm to be used to send the PRB of CSI-RS based on the PRB index according to table 1.
Table 1
[table 1]
Figure BDA00002127367100121
In table 1, when confirming that PRB sends CSI-RS with the interval of rule, offset (skew) value is the variable that is used for confirming position at interval.Even when in the PRB that as above confirms, sending CSI-RS, also can be according to the mode application solution 1 and 2 identical with 4 with following solution 3.
Solution 3: transport CSI-RS if the PRB index is i and this PRB, then use or (CSI-RS mode type of (i-offset)/L) mod N.
Solution 4: transport CSI-RS if the PRB index is i and this PRB, then use individual CSI-RS mode type.
In LTE (or LTE-A) system, can notify such CSI-RS sending method to UE through signaling.Just, in LTE (or LTE-A) system, can notify one of said first to fourth solution of UE and CSI-RS mode type, and send CSI-RS with the CSI-RS mode type of confirming by the PRB index to UE in the CSI-RS transmitting time.
Fig. 8 be illustrate according to example embodiment of the present invention, in having the different PRB of four kinds of CSI-RS patterns the figure of the rule of the CSI-RS of transmitting antenna port alternately.
With reference to Fig. 8, each CSI-RS pattern is to be designed for the CSI-RS that in four OFDM symbols, sends.In this case, define four kinds of CSI-RS mode types (being that type A is to type D) as shown in Figure 8, the feasible CSI-RS that can in single OFDM symbol, send all antenna ports.How divide among a plurality of PRB in system bandwidth the resource that is used in CSI-RS can continue to use described with reference to Fig. 7, use the CSI-RS mode type of PRB index to confirm method.
Being used to shown in Fig. 6 and 8 utilized the CSI-RS pattern of the transmitted power of all antenna ports, it is characterized in that the circulation rotation with the CSI-RS corresponding antenna port that will send.In the situation of Fig. 8, observe the the 5th, the 6th, the 9th and the 10OFDM symbol in the CSI-RS of the antenna port that sends in time domain circulation rotation.This circulation rotation characteristic is used to define the CSI-RS pattern of the transmitted power that is used for all antenna ports.
When designs C SI-RS sends, should consider which resource a plurality of eNB distribute be used for the CSI-RS that CSI-RS sent and be used for a plurality of sub-districts of an eNB.CSI-RS is used for UE to support the signal of LTE-A operation.So in order to measure radio channel state more accurately, this eNB can be that CSI-RS is sent in each sub-district to be higher than the power level of the power level that is used for the data-signal transmission.The transmitted power that is provided for the CSI-RS transmission is higher than the transmitted power that is used for the data-signal transmission and means that the transmitted power of the RE that transports CSI-RS is higher than the transmitted power of the RE that transports data.Send in the situation of CSI-RS in identical RE position distributing to transmitted power and the different sub-district that CSI-RSRE is higher than the transmitted power of data RE, the CSI-RS that different districts sends is interfering with each other probably.In this case, be positioned at relative higher transmit power, also reduced the positive effect of channel measurement even work as CSI-RS.Therefore, even need a kind of method that under higher relatively CSI-RS transmitted power, also can accurately carry out channel measurement.In order to address this problem, example embodiment of the present invention proposes to use the independent CSI-RS pattern that can distribute to many sub-districts.In example embodiment of the present invention, define a plurality of CSI-RS to distribute to the sub-district of forming this cellular system.
Fig. 9 be illustrate according to example embodiment of the present invention, design is with the figure of the CSI-RS pattern of distributing to a plurality of sub-districts in the GSM.
With reference to Fig. 9, show a plurality of CSI-RS patterns that CSI-RS is transported in design.So distribute said CSI-RS pattern to make said sub-district use these resources, send the overlapping of position with the CSI-RS that avoids the sub-district as much as possible in different time and frequency.Distribute said CSI-RS pattern with CSI-RS that in identical OFDM symbol, sends many antenna ports and the different resource that in time domain, uses different OFDM symbols.In the example that uses identical OFDM symbol, so designs C SI-RS pattern makes the CSI-RS that alternately arranges antenna port to occupy different resources in the frequency domain in system bandwidth.
6 kinds of CSI-RS mode assignments that define among Fig. 9 are given the overlapping of the position of different sub-districts with the mode scattered to avoid being used for CSI-RS as much as possible and send.In Fig. 9, CSI-RS pattern 0 is by forming with CSI- RS pattern 2,3,4 RE different with 5 RE.For this reason, even increase the transmitted power of other sub-district with the CSI-RS of CSI- RS pattern 2,3,4 and 5 transmissions, UE also can use the CSI-RS of CSI-RS pattern 0 transmission and not have extra interference to come measured channel with this sub-district.The reason why CSI-RS that sends with CSI-RS pattern 0 is not disturbed by the CSI-RS that sends with CSI- RS pattern 2,3,4 and 5 is because use different time and frequency resource, and no matter CSI-RS antenna port number can both be realized this point.Be used for the exemplary case of two antenna ports sending CSI-RS, can be through the generation that prevents at the position transmission CSI-RS that is used for antenna port 0 and 1 to disturb.
In Fig. 9, CSI-RS pattern 0 can cause interfering with each other with CSI-RS pattern 1.Be equal to or less than 4 and be equal to or less than with the number of antennas that CSI-RS pattern 1 is sent CSI-RS under 4 the situation in the number of antennas of sending CSI-RS with CSI-RS pattern 0, do not interfere with each other with the CSI-RS of CSI- RS pattern 0 and 1 transmission.When the number of antennas of sending CSI-RS with CSI-RS pattern 0 greater than 4 or disturb greater than 4 the time with the number of antennas of CSI-RS pattern 1 transmission CSI-RS.The reason that interference occurs under some condition of limited is because so designs C SI-RS pattern makes CSI-RS in same OFDM symbol, replace.Just, in same OFDM symbol, the order of sending the antenna port of CSI-RS with CSI-RS pattern 0 is 0,4,1,5,2,6,3 and 7, and the order of sending the antenna port of CSI-RS with CSI-RS pattern 1 is 4,0,5,1,6,2,7 and 3.
To likewise be applied to CSI- RS pattern 1,2,3,4 and 5 about the rule that CSI-RS pattern 0 is described.In the GSM that can the CSI-RS pattern that in example embodiment of the present invention as shown in Figure 9, defines is applied to be made up of a plurality of sub-districts.
Figure 10 be illustrate according to example embodiment of the present invention, adopt figure like the cellular network layout of the GSM of the CSI-RS pattern that defines among Fig. 9.
With reference to Figure 10, this GSM is made up of the hexagon coverage of 7 independent eNB, and each coverage is divided into three sub-districts.In three sub-districts of each coverage, send CSI-RS with different CSI-RS patterns.For example, the eNB with three sub-districts 1010,1020 and 1030 sends CSI-RS with CSI-RS pattern 0 in sub-district 1010, in sub-district 1020, send CSI-RS with CSI-RS pattern 4, and in sub-district 1030, send CSI-RS with the CSI-RS mode 3.
In order to give the sub-district of GSM as shown in Figure 10 like the CSI-RS mode assignments that defines among Fig. 9, example embodiment of the present invention proposes to use sub-district ID.According to example embodiment of the present invention,, then confirm CSI-RS pattern ID by formula (1) if this sub-district ID is NCell_ID.
CSI_RS pattern ID=NCell_ID mod 6
.... formula (1)
Utilize formula (1), can come six kinds of CSI-RS patterns of distribution diagram 9 according to the sub-district ID that distributes to each sub-district, and without signaling independent between this eNB and the UE.Except using the method for formula (1), can also confirm to notify the CSI-RS pattern to UE through high-level signaling more to what CSI-RS pattern of cell allocation and with the form of control information.
A kind of method of the CSI-RS of distribution pattern is that the CSI-RS pattern classification is become the CSI-RS that uses each group more than two groups and from different purpose.For example, can six kinds of CSI-RS patterns of Fig. 9 be divided into two groups, i.e. A group and B group.In this case, suppose that the A group comprises CSI-RS pattern 0, CSI-RS pattern 2 and CSI-RS pattern 4, and the B group comprises CSI-RS pattern 1, CSI-RS mode 3 and CSI-RS pattern 5.If in this way six kinds of CSI-RS mode packet of Fig. 9 are become A group and B group, then can avoid A to organize and B organizes the overlapping between the CSI-RS of the CSI-RS pattern in every group.Just, so designs C SI- RS pattern 0,2 makes at different location arrangements CSI-RS with 4.
Under the situation that the CSI-RS pattern is divided into the g group and distributes, can confirm that the CSI-RS mode assignments is following according to sub-district ID.Having distributed the sub-district ID of sub-district of the CSI-RS pattern of g group is NCell_ID, and the g group has Ng kind CSI-RS pattern, is confirmed the CSI-RS pattern of respective cell by formula (2).
The CSI_RS pattern ID=NCell_ID mod Ng of g group
Formula (2)
In formula (2), through with the synthetic g group of Ng kind CSI-RS modal sets and then to said CSI-RS mode assignments from 0 to N g-1 index obtains " the CSI_RS pattern ID of g group ".For example, if the g group comprises the CSI- RS pattern 0,2 and 4 of Fig. 9, the CSI-RS pattern ID of the CSI-RS pattern that then comprises in the g group becomes 0,1 and 2.
Figure 11 be illustrate according to example embodiment of the present invention, design is with the figure of the CSI-RS pattern of distributing to a plurality of sub-districts in the GSM.
The CSI-RS pattern of describing among Figure 11 is used for sending at a plurality of OFDM symbols the CSI-RS of a plurality of antenna ports, and so designs on the different resource that makes in time domain and frequency domain and send CSI-RS.If there are two kinds of CSI-RS patterns using identical OFDM symbol, alternately distribute different resources on the frequency domain then for the CSI-RS of different antennae port.
With reference to Figure 11, give the overlapping of the position of different sub-districts with the mode that distributes with six kinds of CSI-RS mode assignments that define among Figure 11, as said with reference to Fig. 9 to avoid being used for CSI-RS as much as possible and send.In Figure 11, CSI-RS pattern 0 is by forming with CSI- RS pattern 2,3,4 RE different with 5 RE.For this reason, even increase the transmitted power of other sub-district with the CSI-RS of CSI- RS pattern 2,3,4 and 5 transmissions, UE can not have extra interference ground measured channel with the CSI-RS that this sub-district uses CSI-RS pattern 0 to send yet.Why the CSI-RS that sends with CSI-RS pattern 0 is not disturbed by the CSI-RS that sends with CSI- RS pattern 2,3,4 and 5, be because use different time and frequency resource, and no matter CSI-RS antenna port number can both be realized this point.Be used for the exemplary case of two antenna ports sending CSI-RS, can be through the generation that prevents at the position transmission CSI-RS that is used for antenna port 0 and 1 to disturb.
In Figure 11, CSI-RS pattern 0 can cause interfering with each other with CSI-RS pattern 1.Be equal to or less than 4 and be equal to or less than with the number of antennas that CSI-RS pattern 1 is sent CSI-RS under 4 the situation in the number of antennas of sending CSI-RS with CSI-RS pattern 0, do not interfere with each other with the CSI-RS of CSI-RS pattern 0 and 1 transmission.When the number of antennas of sending CSI-RS with CSI-RS pattern 0 greater than 4 or disturb greater than 4 the time with the number of antennas of CSI-RS pattern 1 transmission CSI-RS.Interference occurs under some condition of limited, is because so designs C SI-RS pattern makes CSI-RS in same OFDM symbol, replace.For example, when using CSI-RS pattern 0, transmitting antenna port 0,4,2 and 4 CSI-RS in the 9OFDM symbol, and in the 10OFDM symbol transmitting antenna port 5,1,7 and 3 CSI-RS.Simultaneously, when using CSI-RS pattern 1, transmitting antenna port 5,1,7 and 3 CSI-RS in the 9OFDM symbol, and in the 10OFDM symbol transmitting antenna port 0,2,4 and 6 CSI-RS.In this way, so use CSI-RS pattern 0 and CSI-RS pattern 1 in two different OFDM symbols, to send the CSI-RS of different antennae port, make and when the number of antenna port is equal to or less than 4, can carry out transmission by interference-free.
Fig. 9 and 11 shows CSI-RS pattern available in a PRB, and its definition is used for the transmission of CSI-RS, comes the method to cell allocation sub-district ID and formula (1) and (2) have defined example embodiment according to the present invention.Designs C SI-RS is to be applicable to the various operation scenarios in the LTE-A system.One of important operation scene of LTE-A system is the heterogeneous network of sub-district that has the coverage of different size.In heterogeneous network environment, relatively little on the size (being that diagonal is several meters) coexists as in the identical geographic range with the sub-district of big (being that diagonal is several kms).In this case, require to rely on cell type and use CSI-RS differently.
For the different CSI-RS that depend on cell type are provided, example embodiment of the present invention has proposed a kind of a PRB to be divided into a plurality of zones and in the method for the multiple CSI-RS pattern of each zone definitions.
Figure 12 be illustrate according to example embodiment of the present invention, defined the figure of the PRB in three CSI-RS zones therein.
With reference to Figure 12, CSI-RS zone A is used for sending the CSI-RS of undersized sub-district, and the CSI-RS area B is used for sending the CSI-RS in the sub-district of size, and then the CSI-RS zone C is used for sending the CSI-RS of large-sized sub-district.
Figure 13 be illustrate according to example embodiment of the present invention, in comprising the cellular environment of various types of sub-districts, send the figure of the rule of CSI-RS.With reference to Figure 13, show the dependence cell size and come to the dissimilar CSI-RS of cell allocation.The reason that resource division is become to rely on a plurality of CSI-RS zone of sub-district characteristic allocation is to manage effectively the CSI-RS resource through identical CSI-RS resource is distributed to the sub-district with similar features.
The CSI-RS resource allocation based on cell type as shown in Figure 13 can be carried out as follows:
1.eNB being sent resource division, the CSI-RS that is given becomes a plurality of CSI-RS zone.
2.eNB confirm the type of the sub-district that each CSI-RS zone is distributed to.
3.eNB confirm the type (for example, millimicro, little and grand) of respective cell.
4.eNB confirm to be used for the CSI-RS pattern in this CSI-RS zone and to this CSI-RS pattern of this cell allocation based on cell type.
The CSI-RS pattern that here, can combine to describe in Fig. 9 and 11 is carried out the CSI-RS resource allocation.For example, when in Figure 11 latter two OFDM symbol definition be CSI-RS zone A and remaining during for the CSI-RS area B, then only CSI-RS pattern E is distributed to the CSI-RS model F and classifies as the sub-district of using the regional A of CSI-RS.
Figure 14 A to 14C be illustrate according to example embodiment of the present invention, design is with the figure of the CSI-RS pattern of distributing to a plurality of sub-districts in the GSM.
More specifically, Figure 14 A shows and is designed to have three kinds of CSI-RS patterns that the CSI-RS transmission position that does not overlap is used to support eight CSI-RS antenna ports.Figure 14 B shows and is designed to have six kinds of CSI-RS patterns that the transmission position that does not overlap is used to support four CSI-RS antenna ports.Figure 14 C shows and is designed to have 12 kinds of CSI-RS patterns that the transmission position that does not overlap is used to support two CSI-RS antenna ports.The CSI-RS pattern that Figure 14 A describes in the 14C is characterised in that available CSI-RS model number increases along with the minimizing of CSI-RS antenna port number.
To 14C, the number of available CSI-RS pattern depends on the number of antenna port and changes with reference to Figure 14 A.In this case, confirming the method for CSI-RS for each sub-district also has nothing in common with each other.At antenna port number shown in Fig. 9 or Figure 11 is eight or four and define in the exemplary case of six kinds of CSI-RS patterns, can use formula (1) to confirm CSI-RS pattern ID regardless of the number of antenna port.When like Figure 14 A when number of antennas shown in the 14C is eight, four and two, define three, six and 12 kind of CSI-RS pattern respectively.In this case, the CSI-RS pattern is confirmed as follows:
The number of the CSI-RS antenna of the continuous sub-district of step 1.eNB notice UE.
Step 2.UE uses formula (3) to confirm to support the CSI-RS pattern of CSI-RS number of antennas.
CSI_RS pattern ID=NCell_ID mod NA
Formula (3)
In formula (3), the value of NA depends on the number of CSI-RS antenna port and changes.The NA value is 12 when the CSI-RS number of antennas is 2, is 6 when the CSI-RS number of antennas is 4, and is 3 when the CSI-RS number of antennas is 8.
In order to use formula (3) to confirm the CSI-RS pattern, eNB and UE must sharing informations, and in this case, UE can be based on the CSI-RS pattern of being confirmed by the CSI-RS port number of eNB notice to use.The method can be applied to that NA has a value and typically when NA discerns according to CSI-RS antenna port number.
Figure 15 be illustrate according to example embodiment of the present invention, interference-free sends the figure of the rule of CSI-RS in a plurality of sub-districts.
With reference to Figure 15, in sub-district separately, send CSI-RS with the different subframes that have the different time deviant.Can use one of two kinds of methods between eNB and UE, to share the time migration of the CSI-RS that sends by each sub-district.The first, eNB confirms the time offset value of each sub-district in advance, and sends this time offset value through high-level signaling more with the form of control information.The second, eNB and UE use previous negotiation method generation time deviant.
In Figure 15, the eNB of sub-district 1 sends CSI-RS in subframe 1210, and the eNB of sub-district 2 sends CSI-RS in subframe 1220, and the eNB of sub-district 3 sends CSI-RS in subframe 1230.
It is favourable for many sub-districts, sending CSI-RS with the time offset value of different subframes, because the CSI-RS that is sent by different districts can be not interfering with each other.But, in the situation of LTE that works in time division duplex (TDD) pattern and LTE-A system, can be limited in the radio frames that use is made up of 10 subframes and be used for the subframe that down link sends.In this case, must in some specific subframe, send CSI-RS, and as a result of, be difficult in the CSI-RS that distributes fully in the subframe unit and send by a plurality of sub-districts.Under the situation of CSI-RS that in subframe unit, do not distribute fully, can be through reducing the interference between the CSI-RS that in a plurality of sub-districts, sends to cell allocation CSI-RS pattern as shown in Figure 11.This means in identical subframe the CSI-RS that sends different districts with different CSI-RS patterns.
Figure 16 illustrates according to the figure of rule example embodiment of the present invention, in subframe, send the CSI-RS of a plurality of sub-districts with different CSI-RS patterns.
With reference to Figure 16, CSI-RS is not still sent in sub-district 1 in the subframe of reference number 1330 expressions in the subframe of reference number 1320 expressions.CSI-RS is not still sent in sub-district 2 in the subframe of reference number 1360 expressions in reference number 1350 expressions, the same with the subframe at its CSI-RS place of sub-district 1 transmission subframes.In Figure 16; Sub-district 2 with the same subframe that uses sub-district 1 in send CSI-RS; But the CSI-RS pattern that use sub-district 2 (being the CSI-RS pattern of reference number 1340 expressions) is different from the CSI-RS pattern of using sub-district 1 (being the CSI-RS pattern of reference number 1310 expressions), avoids the interference between the CSI-RS thus.
In the LTE-A system, CSI-RS is used to measure the state of the downlink channel of the sub-district that UE belongs to.The CSI-RS that this UE uses a sub-district to send measures the downlink channel of respective cell, but the CSI-RS that for this UE, also can use two or more sub-districts to send measures downlink channel., can carry out this UE the measurement of the downlink channel of the CSI-RS that sends many sub-districts when receiving the signal of coordinating in multiple spot (CoMP) delivery plan.Under the situation that CoMP sends, a plurality of eNB cooperations are sent to single UE.At this time, said eNB considers the precoding of other eNB and carries out precoding and send signal to said UE simultaneously.
In order to make a plurality of eNB support the CoMP transmission of single UE, this UE must possess the ability of the channel status of measuring the eNB relevant with this CoMP transmission.Just, this UE can measure the CSI-RS of said a plurality of sub-districts and send measurement result to corresponding eNB.Example embodiment of the present invention has proposed a kind of CSI-RS sending method that is used for the CoMP transmission of novelty.Said foundation CSI-RS sending method example embodiment of the present invention, that be used for CoMP is characterized in that sending CoMP CSI-RS and non-CoMP CSI-RS at different time point.Just, according to the subframe of transporting CSI-RS, between CoMP CSI-RS and non-CoMP CSI-RS, distinguish the CSI-RS of individual cells.
Figure 17 sends the figure of the rule of CoMP CSI-RS and non-CoMP CSI-RS according to example embodiment of the present invention, in the sub-district of GSM.
In Figure 17, send non-CoMP CSI-RS or CoMP CSI-RS at interval with the very first time, in second time interval, send CoMP CSI-RS and send each non-CoMP CSI-RS at interval with the very first time.Here, the very first time can be the duration corresponding with 5 subframes at interval, and second time interval can be the duration corresponding with 15 subframes.
With reference to Figure 17, in the subframe pattern represented, send non-CoMPCSI-RS like reference number 1420, and as the represented painted subframe of reference number 1410 in transmission CoMP CSI-RS.In not having the subframe of mark, for example the subframe of reference number 1430 expressions is not sent CSI-RS.In the demonstrative structure of Figure 17, per 5 milliseconds are sent CSI-RS in the CSI-RS that sends, and per 15 milliseconds are sent CoMP CSI-RS, and remaining CSI-RS right and wrong CoMP CSI-RS.In order to send CoMP CSI-RS and non-CoMP CSI-RS as shown in Figure 17, should confirm to transport the subframe of CSI-RS and distribute said subframe to be used to transport CoMP CSI-RS and non-CoMP CSI-RS.As method described with reference to Figure 17, that be used to send CoMP CSI-RS and non-CoMP CSI-RS help being used for CSI-RS sends and constantly assigned radio resource send CoMP CSI-RS and non-CoMP CSI-RS.
In order to send CoMP CSI-RS and non-CoMP CSI-RS as shown in Figure 17, eNB notice UE:CSI-RS sends the subframe and the rule of transporting the subframe of non-CoMP CSI-RS of transporting CoMP CSI-RS at interval with differentiation.
Figure 18 be illustrate according to example embodiment of the present invention, in the sub-district of GSM, send the figure of the rule of CoMP CSI-RS and non-CoMP CSI-RS.
With reference to Figure 18, send non-CoMP CSI-RS at interval with the very first time, and send CoMP CSI-RS with second time interval, second interval greater than the very first time at interval.Here, the very first time equaled for 5 subframe duration at interval, and second time interval equaled for 15 subframe duration.
As shown in Figure 18, in like the subframe pattern of reference number 1520 expressions, send non-CoMP CSI-RS, and in like the painted subframe of reference number 1510 expressions, send CoMP CSI-RS.In not having the subframe of mark (such as the subframe represented), do not send CSI-RS by reference number 1530.In Figure 18, be shown the duration that is provided for sending CoMP CSI-RS and non-CoMP CSI-RS discretely.Method unlike Figure 17; It is at first confirmed to be used to send the duration of CSI-RS and then distributes the determined duration to be used to send CoMP CSI-RS and non-CoMP CSI-RS, and the method for Figure 18 is the duration of confirming to be used to send CoMP CSI-RS and non-CoMP CSI-RS respectively.As a result, per 15 milliseconds are sent CoMP CSI-RS in Figure 18, and per 5 milliseconds of non-CoMP CSI-RS of transmission.
Figure 17 and 18 shows in the sub-district with predetermined sending duration transmission CoMP CSI-RS and the method for non-CoMP CSI-RS.Confirmed to send the CSI-RS of which kind of type in which subframe.In addition, it is very important how to generate CoMP CSI-RS.
Send the CoMP CSI-RS that proposes in the example embodiment of the present invention to compare different modes with non-CoMP CSI-RS.That is, whether be CoMP CSI-RS and generate various signals to eNB if depending on the CSI-RS that will in the sub-district, send.Use is sent the CoMP CSI-RS that proposes in the example embodiment of the present invention with the virtual-antenna port that non-CoMP CSI-RS compares lesser number.Antenna is virtual to refer to when having N physical antenna, sends identical signal and makes the signal that illustrates seemingly by M antenna transmission.For example, if send signal by two antennas with transmitted power P1 and P2, the signal that is then received by receiver is to be sent with the transmitted power of P1+P2 by a transmitting antenna seemingly.
Figure 19 be illustrate according to example embodiment of the present invention, in GSM, send the figure of the rule of CoMP CSI-RS and non-CoMP CSI-RS.Under the situation of supposition two sub-districts transmission CSI-RS, describe Figure 19.
With reference to Figure 19; Transport the non-CoMP CSI-RS that sends by sub-district 1 like reference number 1620 represented subframe patterns; Transport the CoMP CSI-RS that sends by sub-district 1 like reference number 1640 represented painted subframes, and do not transport CSI-RS like reference number 1630 represented unlabelled subframes.Transport the non-CoMP CSI-RS that sends by sub-district 2 like the subframe pattern of reference number 1660 expressions; Transport the CoMP CSI-RS that sends by sub-district 2 like reference number 1680 represented painted subframes, and do not transport CSI-RS like reference number 1695 represented unlabelled subframes.
In Figure 19, that the subframe that is used to send non-CoMP CSI-RS is transported is 2 that send by sub-district 1 and sub-district, like the CSI-RS of reference number 1610 and 1670 represented layouts.By reference number 1610 and 1670 expressions, be used in six kinds of CSI-RS patterns that CSI-RS pattern that subframe is sent non-CoMP CSI-RS is described in from Figure 11.In sending the situation of non-CoMP CSI-RS, each sub-district to all antenna ports send can measured channel CSI-RS.In addition, represented and send under the situation of CoMP CSI-RS like the reference number of Figure 19 1650 and 1690, the CSI-RS of the antenna port of the number that reduces is sent in each sub-district.Can use virtual reference number 1650 and 1690 methods of carrying out like Figure 19 represented, that reduce the antenna port number that sends CSI-RS of aforementioned antenna.In the situation of sending CoMP CSI-RS by this way, reduced the number of the antenna port of CSI-RS, and the decreased number of the antenna port of the CSI-RS that therefore sends by every sub-district, but the transmitted power of each antenna has increased.Just, in situation, send CoMP CSI-RS with the transmitted power of the twice of non-CSI-RS by the reference number 1650 of Figure 19 and 1690 expressions.
Why send CoMP CSI-RS as shown in Figure 19, to be positioned at cell edge in order improving, to receive the receptivity of the UE a little less than the signal strength signal intensity.Just, if CoMP CSI-RS is sent in the sub-district, then can reduce the antenna port number of each sub-district that UE will measure and be increased in the transmitted power of line cap every day, this causes the improvement of the receptivity of UE.Be distributed in the situation of cell edge at UE, it is favourable increasing the reception signal strength signal intensity of each layer rather than increasing the spatial reuse gain along with the increase of the number of plies.In the situation of sending CoMP CSI-RS discretely, as shown in Figure 19, do not reduce antenna port, the sub-district number that the CSI-RS number that UE receives is relevant with CoMP is corresponding.That is, suppose that in CoMP UE 1 receives signals with sub-district 2 from the sub-district, then this UE must measure altogether 16 antenna ports and to this eNB feedback channel metrical information.Layer in big quantity is unfavorable for receiving in the situation of signal, on the antenna port that increases number, non-CoMP is carried out channel measurement and a large amount of relatively channel measurement information of report is inefficient.
Send in the situation of CSI-RS in many sub-districts, use and to avoid the conflict between the CSI-RS of different districts like the multiple CSI-RS pattern of describing in Fig. 9 and 11.The another kind of method of improving the CSI-RS receptivity is to use inhibition (muting) or blanking (blanking).Suppress to refer to not send the signal that is positioned at specific RE position.That is, 1 sends on the RE at CSI-RS place in the sub-district, and any signal is not sent in sub-district 2, so that the CSI-RS of UE measurement cell 1 transmission more accurately.
Figure 20 be illustrate according to example embodiment of the present invention, in GSM, use the inhibition scheme to send the figure of the rule of CSI-RS.
With reference to Figure 20, CSI-RS is sent with different CSI-RS patterns in a plurality of sub-districts, and each sub-district is confirmed the employed CSI-RS pattern of neighbor cell and suppressed the resource that neighbor cell sends its CSI-RS place.
Under following hypothesis, describe Figure 20: the CSI-RS Mode A of sub-district 1 usefulness Figure 11 sends CSI-RS, and the CSI-RS pattern C of sub-district 2 usefulness Figure 11 of abutting subdistrict 1 sends CSI-RS.In this case, the CSI-RS pattern of sub-district 1 has the instance represented like reference number 1710,1730 and 1760.In the RE that distributes to the respective antenna port according to the CSI-RS antenna port number of sub-district 1, send CSI-RS.Send in the situation of CSI-RS at the CSI-RS pattern C of sub-district 2 usefulness Figure 11, suppress the signal of sub-district 1 transmission according to the CSI-RS antenna port number of sub-district 2.If the CSI-RS antenna port number of sub-district 2 is 2, then sub-district 1 is carried out on the resource of reference number 1720 expressions and is suppressed to help the channel measurement based on the CSI-RS of sub-district 2.If the CSI-RS antenna port number of sub-district 2 is 4, then sub-district 1 is carried out on the resource of reference number 1740 and 1750 expressions and is suppressed.Equally, if the CSI-RS antenna port number of sub-district 2 is 8, then sub-district 1 is carried out on the resource of reference number 1770 and 1780 expressions and is suppressed.
Figure 21 be illustrate according to example embodiment of the present invention, in GSM, use the inhibition scheme to send the figure of the rule of CSI-RS.Figure 21 illustrates the resource at 2 execution inhibition places, sub-district when CSI-RS is sent in sub-district 1.
With reference to Figure 21, CSI-RS is sent in sub-district 1, and inhibition is carried out in sub-district 2 on the resource of the CSI-RS that transports sub-district 1, to help the channel measurement based on the CSI-RS of sub-district 2.Equally, CSI-RS is sent in sub-district 2, and on the resource of the CSI-RS that transports sub-district 1, carries out and suppress, to help the channel measurement based on the CSI-RS of sub-district 1.Here, reference number 1810,1820,1830,1840,1850,1860 and 1870 is similar to the reference number 1710,1720,1730,1740,1750,1760 and 1770 of Figure 20, and the therefore description that concisely will omit them in order to explain.
Shown in Figure 20 and 21, when CSI-RS was sent in a plurality of sub-districts, each sub-district was carried out on the RE of the CSI-RS that transports other sub-district and is suppressed to help UE to estimate channel based on the CSI-RS of other sub-district.Should the inhibition scheme in order to adopt, the information about the CSI-RS pattern must be shared in said sub-district.Promptly; For the inhibition of carrying out CSI-RS is sent; ENB to specific cell transmission CSI-RS will be appreciated that the information about the employed CSI-RS pattern of eNB of sending CSI-RS as shown in Figure 21 as shown in Figure 20, and the antenna port number that sends CSI-RS.Adopting inhibition scheme as shown in Figure 21 to be used for the situation that CSI-RS as shown in Figure 17 sends, their CSI-RS pattern and CSI-RS antenna port number must be shared in relevant sub-district.
Figure 20 and 21 illustrates the inhibition scheme of carrying out in the subframe of sending CSI-RS.Yet, also can be in the same way with the subframe that should the inhibition scheme be used for not existing CSI-RS.Equally, this inhibition scheme shall not be applied in the subframe of the CSI-RS that does not have other sub-district, but partly is applied in such subframe.
Figure 22 be illustrate according to example embodiment of the present invention, the inhibition scheme is applied to a plurality of sub-districts with the squint figure of the rule in the situation of sending CSI-RS of different subframes.
With reference to Figure 22, CSI-RS is sent in two sub-districts, and squints with different subframes and to send the CSI-RS of sub-district separately.The sending mode that depends on CSI-RS in two sub-districts is confirmed the inhibition scheme.That is, sub-district 1 is carried out on the resource of reference number 1930 expressions in the subframe 1915 in Figure 22 and is suppressed.Why on subframe 1915, suppressing the signal that send sub-district 1, is in order to help UE to measure the CSI-RS that sends like reference number 1965 represented sub-districts 2.
In Figure 22, can observe and be not the whole resource of the subframe that suppresses to be applied to wherein to send CSI-RS but the part of this subframe.Partly using this inhibition is in order to reduce the performance degradation of contingent data-signal owing to suppressing.In Figure 22, can also observe CSI-RS and take place with per 20 sub-frame with per 5 sub-frame generation and inhibition.For the mode with Figure 22 is sent CSI-RS, a sub-district will be appreciated that the subframe skew of the CSI-RS in other sub-district and sends the interval.
In Figure 20,21 and 22, under the situation of supposition transmission CSI-RS in all PRB, using should the inhibition scheme.Yet, can be in a like fashion with should the inhibition scheme being applied to the only situation of transmission CSI-RS in some PRB.
Figure 23 be illustrate according to example embodiment of the present invention, the inhibition scheme is applied to the situation of CSI-RS is sent in two sub-districts in some PRB the figure of rule.
With reference to Figure 23; Sub-district 2 is with suppressing to be applied to the resource like reference number 2020 expressions; Simultaneously CSI-RS is sent in sub-district 1 on the same asset represented like reference number 2010; And sub-district 1 is suppressing to be applied to the resource like reference number 2030 expressions, and CSI-RS is sent in sub-district 2 on the same asset represented like reference number 2040 simultaneously.
Figure 24 illustrates the flow chart that receives the method for CSI-RS according to UE in the GSM of multiple CSI-RS pattern work example embodiment of the present invention, that in having Fig. 9 or Figure 11, describe.
With reference to Figure 24, in step 2105, UE confirms in corresponding sub-district, to carry out the sub-district ID of the eNB that sends, and then in step 2110, confirms CRS position and scrambling, and receives the system information about CSI-RS.Here, sub-district ID is used for confirming the information about CRS position and scrambling, and the UE of acquisition CRS information can receive the system information of respective cell.The system information that receives in step 2110 comprises the control information about CSI-RS.Can directly receive control information at this UE of step 2110 about CSI-RS from eNB.As be under the situation of function of sub-district ID with reference to the CSI-RS pattern of the transmission of Fig. 9 and the 11 described CSI-RS that are used for specific cell; This UE confirms the system information of sub-district ID to obtain to send about CSI-RS of corresponding eNB, for example CSI-RS position and scrambling.
Then, this UE receives and handles subframe.If received subframe, then this UE is based on the information that step 2110 obtains and confirms whether this subframe transports CSI-RS in step 2125.Transport CSI-RS if confirm this subframe, then this UE uses this CSI-RS to measure downlink channel status in step 2130.Next step, in step 2135, this UE confirms whether this subframe is transported the destination and be it self physical down link sharing channel (PDSCH).Transport this PDSCH if confirm this subframe, then this UE confirms whether CSI-RS is present in the frequency resource of sending this PDCCH in step 2140, promptly on the PRB.Be used among the PRB that sends said PDSCH if CSI-RS is present in branch, then this UE considers to be present in CSI-RS among the PRB that is distributed and carries out PDSCH and receive operation in step 2145, and in step 2115 wait next son frame.
Do not transport said PDSCH if in step 2135, confirm this subframe, then this UE waits for next subframe in step 2115.Equally; If in step 2140, being used among the PRB that sends said PDSCH at branch does not have CSI-RS (promptly; If do not receive the subframe of transporting CSI-RS); Then this UE considers that CSI-RS is not present among the PRB that is distributed and carries out said PDSCH and receive operation in step 2155, and in step 2120, waits for the next son frame.If do not transport CSI-RS in definite this subframe of step 2125; Then this UE confirms whether this subframe transports PDSCH in step 2150; And if PDSCH is included in this subframe, then in step 2155, carries out PDSCH and receive operation, and in step 2120, wait for the next son frame.If do not have PDSCH to be contained in this subframe in step 2150, then this UE turns back to step 2120 to wait for next subframe with process.
Figure 25 illustrates the flow chart that receives the method for CSI-RS according to UE in GSM example embodiment of the present invention, multiple CSI-RS pattern work that use the inhibition scheme, that in using Fig. 9 or Figure 11, describe.
With reference to Figure 25, this UE confirms in respective cell, to carry out the sub-district ID of the eNB that sends in step 2205, and then in step 2210, confirms CRS position and scrambling, and receives the system information about CSI-RS.Here, sub-district ID is used for confirming the information about CRS position and scrambling, and the UE of acquisition CRS information can receive the system information of respective cell.The system information that receives in step 2210 comprises the control information about CSI-RS.Can directly receive control information from eNB at this UE of step 2210 about CSI-RS.The control information that this UE receives from this eNB comprises the inhibition position of this eNB and about the information of the CSI-RS of the sub-district under this UE.Can carry out inhibition in two ways.In first kind of mode, this eNB directly notifies UE should suppress the position, and in the second way, this eNB notifies this UE to suppress the CSI-RS pattern that is applied to.Defining between this eNB and the UE under the situation of multiple CSI-RS pattern, this eNB only need notify this UE to use which kind of CSI-RS pattern to be used for suppressing.The inhibition control information of sending to this UE from this eNB here, comprises subframe skew of corresponding CSI-RS pattern, the number of antennas that will suppress, inhibition interval, inhibition or the like.
After step 2210 was confirmed to suppress control information, this UE received subframe and determines whether to think and will suppress this subframe in step 2225.If confirming to think to suppress this subframe, then this UE confirms whether this subframe is transported the destination and be it self PDSCH in step 2230.If this subframe is transported said PDSCH, then this UE confirms whether the PRB that distributes to this UE has the part of inhibition in step 2235.This UE uses the inhibition control information to confirm whether the part that suppresses exists.If in this PRB, there is not the part that suppresses, then this UE considers not have the part that suppresses to be present in to carry out among the PRB that is distributed PDSCH to receive to operate in step 2250.Otherwise if in step 2235 part of inhibition is arranged in this PRB, then this UE considers that the part that suppresses is present in and carries out PDSCH among the PRB that is distributed and receive operation in step 2240.That is, this UE does not receive the supposition reception of execution signal down of signal in the part that suppresses.After step 2240 was handled said PDSCH, this UE waited for next subframe in step 2215.Equally, after step 2250 was handled said PDSCH, this UE waited for next subframe in step 2220.If confirming not think in step 2225 to suppress this subframe, then confirm at this UE of step 2245 whether this subframe is transported the destination and be it self PDSCH.If transport said PDSCH in this subframe of step 2245, then this process proceeds to step 2250, otherwise this process proceeds to step 2220.If do not transport said PDSCH in this subframe of step 2230, then this process proceeds to step 2215.
Figure 26 be illustrate according to example embodiment of the present invention, eNB uses the inhibition scheme to send the figure of the method for CSI-RS in GSM.
With reference to Figure 26, the exchange of eNB and adjacent eNB relates to the information of the transmission of CSI-RS in step 2305.In step 2305, said eNB is except exchanging said information, and the CSI-RS that also coordinates each sub-district sends.Here, refer to for the coordination in the CSI-RS transmission and distribute the CSI-RS pattern as Fig. 9 and 11 shown in, define with transmission CSI-RS.After information exchange, the information that eNB uses the said CSI-RS of relating to send in step 2310 is confirmed the inhibition position in the down link transmission.Just, this eNB confirms how specifically to use to suppress through confirming inhibition interval, duration and position on frequency domain.Then, send the control information that relates to CSI-RS and inhibition to UE at this eNB of step 2320.During this time, can send the control information that relates to CSI-RS and inhibition with the form of system information.After sending said information, determine whether to think that at this eNB of step 2330 current subframe will transport CSI-RS about CSI-RS and inhibition.
If think that current subframe will transport CSI-RS, then this eNB sends CSI-RS in current subframe in step 2335.Then, this eNB determines whether to think that current subframe accepts inhibition in step 2340, and if think that current subframe takes to suppress, then in step 2345, use the down link that suppresses to carry out this subframe to send.That is, each eNB shares CSI-RS pattern and the CSI-RS antenna port number about neighbor cell.When sending its subframe, this eNB analyzes the CSI-RS pattern determining whether to think that this subframe transports CSI-RS, and if arrive the CSI-RS transmitting time, then in this subframe, send CSI-RS based on this CSI-RS pattern.Equally, if arrive the CSI-RS transmitting time of neighbor cell, then this eNB suppresses counting to carry out on the RE of corresponding number with the CSI-RS antenna port of the CSI-RS pattern of this neighbor cell.Afterwards, this eNB waits for next subframe in step 2325, and when next subframe occurring, this process is returned step 2330.So this operates in each subframe and repeats.
Figure 27 be illustrate according to example embodiment of the present invention, eNB sends the figure of the method for non-CoMP CSI-RS and CoMP CSI-RS in the mobile communication.
With reference to Figure 27, this eNB confirms to belong to the sub-district of CoMP collection in step 2405.This CoMP collection is the set of the relevant a plurality of sub-districts of CoMP transmission.After confirming to participate in the sub-district of this CoMP, this eNB shares in the sub-district that belongs to this CoMP collection and relates to the control information that this CoMP CSI-RS sends in step 2410.In the situation of sending CoMP CSI-RS as shown in Figure 19, this Sharing Information can be included in the CSI-RS pattern of the CoMP CSI-RS that wherein sends said sub-district and the antenna port and the scrambling that will be used to send.Afterwards, this eNB notifies UE information about CoMP CSI-RS and non-CoMP CSI-RS in step 2415.
Then, this eNB determines whether to think that current subframe will transport CSI-RS in step 2425.If think that current subframe will transport CSI-RS, then this eNB determines whether to think that current subframe transports CoMP CSI-RS in step 2430.If think that current subframe transports CoMP CSI-RS, then this eNB sends CoMP CSI-RS in this subframe in step 2240, otherwise this eNB sends non-CoMP CSI-RS in this subframe in step 2435.If do not think that in step 2425 current subframe will be transported CoMP CSI-RS and after step 2440 or 2435 was sent CSI-RS, this eNB proceeded to step 2420 to wait for next subframe.Afterwards, this process is returned step 2425.
As stated, if think that current subframe will transport CSI-RS, then this eNB confirms whether the CSI-RS that will send is CoMP CSI-RS.At this time, if think that current subframe will transport CoMPCSI-RS, then this eNB sends CoMP CSI-RS, otherwise, non-CoMP CSI-RS takes place.Here, CoMP CSI-RS is the CSI-RS that send a plurality of sub-districts, is used for the downlink channel that UE measures these a plurality of sub-districts, and the CoMP collection is the set of participating in the sub-district of this CoMP CSI-RS transmission.Here; This eNB sends CSI-RS in the subframe that is arranged in very first time interval; And in said CSI-RS; Send CoMP CSI-RS and be arranged in the very first time non-CoMP CSI-RS of residue subframe transmission at interval in the subframe that was arranged in for second time interval, wherein second time interval can be a very first time multiple at interval.When sending CSI-RS; Can so design it and make and send non-CoMP CSI-RS and send CoMP CSI-RS in the subframe that had been arranged in for second time interval being arranged in very first time subframe at interval, wherein second time interval was that very first time multiple and the subframe of transporting non-CoMP CSI-RS and CoMP CSI-RS at interval can not overlap on length.Here, CoMP CSI-RS and non-CoMP CSI-RS compare and use fewer purpose virtual-antenna port, and the very first time can equal 5 subframes at interval.
Figure 28 be illustrate according to example embodiment of the present invention, UE receives the flow chart of the method for non-CoMP CSI-RS and CoMP CSI-RS in the mobile communication.
With reference to Figure 28, UE confirms in respective cell, to send the sub-district ID of the eNB of signal in step 2505.This sub-district ID is used to obtain the information about CRS position and scrambling, and UE receives the system information of respective cell based on this CRS information in step 2510.UE confirms CRS position and scrambling and receives the information that relates to CoMP CSI-RS and non-CoMP CSI-RS then in step 2510.The system information of said respective cell comprises the control information that is used to receive CoMP CSI-RS and non-CoMP CSI-RS.In step 2520, UE is based on CoMP CSI-RS and the non-CoMP CSI-RS information that step 2510 obtains, and confirms whether current subframe transports CSI-RS.If transport CSI-RS, then confirm at this UE of step 2525 whether the CSI-RS that in this subframe, transports is CoMP CSI-RS in this subframe of step 2520.If the CSI-RS that in this subframe, transports is CoMP CSI-RS, then measure the CoMP channel based on the scramble sequence and the antenna port of each sub-district at this UE of step 2530.Then, this UE measures based on this and generates the CoMP channel condition information in step 2535, and to this channel information of eNB report.If the CSI-RS right and wrong CoMP CSI-RS that in this subframe of step 2525, transports, then in step 2540, based on the scramble information that this CSI-RS pattern, antenna port and respective cell are sent, UE uses this CSI-RS to measure the channel status of respective cell.Then, this UE measures the generation channel condition information and reports this channel condition information to eNB based on this in step 2545.If do not think that in step 2520 current subframe will be transported CSI-RS and after step 2535 or 2545, this UE proceeds to step 2515 to wait for next subframe.Afterwards, this process turns back to step 2520.So this UE repeats this operation for each subframe.
As stated, according to method example embodiment of the present invention, that handle CSI-RS can be in different PRB the CSI-RS of transmitting antenna port alternately so that manage the transmitted power of all antenna ports of eNB effectively.Method this foundation example embodiment of the present invention, that handle CSI-RS distributes different CSI-RS patterns to give each sub-district; So that avoid the transmission position of the CSI-RS of different districts to overlap; Disturb, send effectively non-CoMP CSI-RS and CoMP CSI-RS thereby suppress signal, and allow UE to send the auxiliary measured channel effectively down of the resource at CSI-RS place suppressing adjacent eNB.
Although illustrate and described the present invention with reference to its specific example embodiment; But it will be appreciated by those skilled in the art that; Under the situation that does not break away from the spirit of liking claims and the defined invention of equivalents thereof enclosed and scope, can carry out the various variations on form and the details therein.

Claims (17)

1. the method for a transmitting channel state information-reference signal (CSI-RS) in OFDM (OFDMA) system, this method comprises:
The CSI-RS mode type confirmed in Physical Resource Block (PRB) index based on subframe;
When thinking that this subframe will be transported CSI-RS, based on said CSI-RS mode type, with first the CSI-RS to the N antenna port distribute to PRB first to N OFDM (OFDM) symbol; And
Transmission comprises the subframe that first CSI-RS to the N antenna port is mapped in PRB wherein,
Wherein first to the N CSI-RS mode type is mapped to first CSI-RS to the N antenna port with mode alternately first to the N OFDM symbol of said PRB.
2. method as claimed in claim 1, confirm that wherein the step of CSI-RS mode type comprises: when said PRB index was i, decision was (i mod N) individual CSI-RS mode type, and wherein N is the number of CSI-RS mode type.
3. method as claimed in claim 2 further comprises: when N=2, in each odd number PRB, sends a CSI-RS mode type and in each even number PRB, sends the 2nd CSI-RS mode type,
Wherein a CSI-RS mode type sends the CSI-RS of first antenna port and in the 2nd OFDM symbol, sends the CSI-RS of second antenna port in an OFDM symbol; And the 2nd CSI-RS mode type sends the CSI-RS of second antenna port in an OFDM symbol and in the 2nd OFDM symbol, send the CSI-RS of first antenna port.
4. method as claimed in claim 1; The step of wherein confirming the CSI-RS mode type comprises: when the PRB index is i; Decision is
Figure FDA00002127367000011
individual CSI-RS mode type; Wherein N is the number of CSI-RS mode type, and K is the maximum of PRB index.
5. method as claimed in claim 4 further comprises: when N=2, in (k/2) individual PRB, sends a CSI-RS mode type and in (k/2-K) individual PRB, sends the 2nd CSI-RS mode type,
Wherein a CSI-RS mode type sends the CSI-RS of first antenna port and in the 2nd OFDM symbol, sends the CSI-RS of second antenna port in an OFDM symbol; And the 2nd CSI-RS mode type sends the CSI-RS of second antenna port in an OFDM symbol and in the 2nd OFDM symbol, send the CSI-RS of first antenna port.
6. method as claimed in claim 1; The step of wherein confirming the CSI-RS mode type comprises: when the PRB index is that i and this PRB are when transporting CSI-RS; Decision is
Figure FDA00002127367000021
or ((i-offset)/L) modN CSI-RS mode type; Wherein N is the number of CSI-RS mode type, and L is the interval number that wherein sends the PRB of CSI-RS.
7. method as claimed in claim 1; The step of wherein confirming the CSI-RS mode type comprises: when the PRB index is that i and this PRB are when transporting CSI-RS; Decision is
Figure FDA00002127367000022
individual CSI-RS mode type; Wherein N is the number of CSI-RS mode type; K is the maximum of PRB index, and L is the interval number that wherein sends the PRB of CSI-RS.
8. the method for a transmitting channel state information-reference signal (CSI-RS) in OFDM (OFDMA) system, this method comprises:
Confirm coordinating the concentrated sub-district of multiple spot (CoMP), and in said sub-district, share the information that relates to the CoMPCSI-RS transmission;
When sending subframe, determine whether to think that this subframe will transport CSI-RS;
When thinking that this subframe will be transported CSI-RS, confirm whether this CSI-RS is CoMP CSI-RS; And
When this CSI-RS is CoMP CSI-RS, send this CoMP CSI-RS; And when this CSI-RS is not CoMP CSI-RS; Send non-CoMP CSI-RS; Wherein CoMP CSI-RS is the CSI-RS that is sent by a plurality of sub-districts; Be used for subscriber equipment (UE) and measure the downlink channel of said sub-district, and the CoMP collection is to participate in the set that the sub-district of CoMP CSI-RS is sent in cooperation.
9. method as claimed in claim 8, wherein Sharing Information comprises the CSI-RS pattern that is used for CoMPCSI-RS and the position of antenna port in said sub-district.
10. method as claimed in claim 9; The step of wherein sending CoMP CSI-RS is included in to send CSI-RS in the very first time subframe at interval; CSI-RS with in the subframe of second time interval transmission is CoMP CSI-RS; And all the other the CSI-RS right and wrong CoMPCSI-RS in the subframe of sending at interval with the very first time, second time interval was a very first time multiple at interval.
11. like the method for claim 10, wherein compare with non-CoMP CSI-RS, CoMP CSI-RS uses the virtual-antenna port of lesser number, and the very first time equals 5 sub-frame at interval.
12. method as claimed in claim 9, the step of wherein sending CoMP CSI-RS comprises:
In with very first time subframe at interval, send non-CoMP CSI-RS and in the subframe in second time interval, send CoMP CSI-RS; Second time interval was a very first time multiple at interval, did not send the subframe of transporting non-CoMP CSI-RS and CoMP CSI-RS each other with overlapping.
13. like the method for claim 11, wherein compare with non-CoMP CSI-RS, CoMP CSI-RS uses the virtual-antenna port of lesser number, and the very first time equals 5 sub-frame at interval.
14. the method for a transmitting channel state information-reference signal (CSI-RS) in OFDM (OFDMA) system, this method comprises:
Share information about the number of the CSI-RS pattern of neighbor cell and CSI-RS antenna port;
When sending subframe, determine whether to think that through analyzing this CSI-RS pattern this subframe will transport CSI-RS;
When the CSI-RS transmitting time then, send this according to said CSI-RS pattern and transport the subframe of CSI-RS; And
In the CSI-RS of one of said neighbor cell transmitting time, send and wherein to suppress the subframe of counting the resource element (RE) of corresponding number with the CSI-RS antenna port of said neighbor cell.
15., wherein give the different CSI-RS pattern of neighbor cell allocation like the method for claim 14.
16. like the method for claim 15, wherein neighbor cell sends CSI-RS with different subframe skews.
17. like the method for claim 15, wherein neighbor cell sends CSI-RS in identical subframe.
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